Topological Transitions in Metamaterials

Abstract: Light-matter interactions can be controlled by manipulating the photonic environment. We uncovered an optical topological transition in strongly anisotropic metamaterials that results in a dramatic increase in the photon density of states-an effect that can be used to engineer this interaction. We describe a transition in the topology of the iso-frequency surface from a closed ellipsoid to an open hyperboloid by use of artificially nanostructured metamaterials. We show that this topological transition manifest… Show more

“…In this work, we experimentally study non-resonant broadband enhancement of the emission from NV centers coupled with hyperbolic metamaterials (HMMs). [12][13][14] Our approach takes advantage of the large photonic density of states (PDOS) in a broad range of wavelengths, which is a striking property of HMMs. 15,16 The PDOS, similar to its electronic counterpart, can be quantified as the volume in k-space between isofrequency surfaces…”

Broadband enhancement of spontaneous emission from nitrogen-vacancy centers in nanodiamonds by hyperbolic metamaterials

“…In this work, we experimentally study non-resonant broadband enhancement of the emission from NV centers coupled with hyperbolic metamaterials (HMMs). [12][13][14] Our approach takes advantage of the large photonic density of states (PDOS) in a broad range of wavelengths, which is a striking property of HMMs. 15,16 The PDOS, similar to its electronic counterpart, can be quantified as the volume in k-space between isofrequency surfaces…”

Broadband enhancement of spontaneous emission from nitrogen-vacancy centers in nanodiamonds by hyperbolic metamaterials

“…These hyperbolic metamaterials have been harnessed for sub-diffraction imaging [35,36], negative-refraction [30,31], photon density of states engineering [37][38][39], heat transfer [40], and so forth. However, the ability to engineer hyperbolic dispersion at will to harness propagating waves with large wavevectors has been a long sought-after goal.…”

Coherence-Driven Topological Transition in Quantum Metamaterials

“…The latter idea arises from the consideration that Dirac-like dispersion cones can be realized in a linear dispersion regime where the metamaterial effective parameters approach zero, allowing for topological transitions to occur in metamaterials. Hyperbolic metamaterials also support ENZ and epsilon near pole (ENP) spectral regions [1,21] that induce band splitting and support such topological transitions [22]. Thus, active tuning of the effective parameters can tune the spectral regions of topological transitions along with the possibility to dynamically study topological transitions in photonic systems.…”

Field-effect induced tunability in hyperbolic metamaterials